Fiber optic cables with access features and methods of making fiber optic cables

ABSTRACT

Cables are constructed with extruded discontinuities in the cable jacket that allow the jacket to be torn to provide access to the cable core. The discontinuities can be longitudinally extending strips of material in the cable jacket.

RELATED APPLICATIONS

This application is a continuation of pending U.S. application Ser. No. 14/730,573, filed Jun. 4, 2015, which is a continuation of U.S. application Ser. No. 13/660,224, now U.S. Pat. No. 9,073,243, filed Oct. 25, 2012, which is a continuation of International Application No. PCT/US11/34309 filed Apr. 28, 2011, which claims the benefit of priority to U.S. Application No. 61/330,038, filed Apr. 30, 2010, each application of which is incorporated herein by reference.

BACKGROUND

Fiber optic cables typically include one or more optical fibers surrounded by a protective polymer jacket. The jacket must be robust enough to endure various environmental conditions, yet must also allow field technicians to access the enclosed optical fibers without undue effort and time. Various solutions have been proposed to provide access to optical fibers in a cable core, including the inclusion of ripcords and other means. U.S. Pat. No. 5,970,196 includes large inserts that can be removable from a cable jacket to allow access to the cable core. The inserts are so large, however, that mechanical performance of the cable may suffer as the size of the inserts allow large sections of the cable/tube jacket to bend and flex in dissimilar modes.

U.S. Pat. No. 7,187,830 discloses the creation of voids filled with liquid or gas, but such voids may also adversely affect structural integrity of some cable jacket types, as well as providing paths for water ingress.

SUMMARY

According to one embodiment, a cable comprises a core and a jacket surrounding the core. The jacket comprises a main portion of a first material, and at least one discontinuity of a second material. The discontinuity extends along a length of the cable, and the bond between the main portion and the discontinuity allows the jacket to be separated at the discontinuity to provide access to the core. The discontinuity may constitute a relatively small portion of the overall jacket area and may remain integral with the jacket after access.

According to a first aspect, the main portion and the discontinuity can be extruded together so that the first and second materials flow together during extrusion, and bond together during cooling. The second material can flow into a trough formed in the first material during extrusion.

According to a second aspect, the second material of the discontinuities can include selected quantities of the first material to enhance bonding between the main portion and the discontinuities.

Those skilled in the art will appreciate the above stated advantages and other advantages and benefits of various additional embodiments reading the following detailed description with reference to the below-listed drawing figures.

BRIEF DESCRIPTION OF THE DRAWINGS

According to common practice, the various features of the drawings discussed below are not necessarily drawn to scale. Dimensions of various features and elements in the drawings may be expanded or reduced to more clearly illustrate the embodiments of the invention.

FIG. 1 is a partial cutaway view of a fiber optic cable according to a first embodiment.

FIG. 2 is a cross section of the cable jacket illustrated in FIG. 1.

FIG. 3 is an isolated cross-sectional view of one of the discontinuities in the cable jacket of FIG. 2.

FIG. 4 is a cutaway view of a coextrusion apparatus used to manufacture cables with discontinuities.

FIG. 5 is a cutaway view of the coextrusion apparatus of FIG. 4 illustrating extrudate material flow.

FIG. 6 illustrates a ring that can be used to modify conventional cable jacketing devices to form discontinuities.

FIG. 7 is a partial cutaway view of a fiber optic cable according to a second embodiment.

DETAILED DESCRIPTION

FIG. 1 is a partial cutaway view of a fiber optic cable 10 according to a present embodiment. The cable 10 comprises a core 20 surrounded by a jacket 30. The jacket 30 has an interior surface 34 that faces the core 20, and an exterior surface 38. The jacket 30 can be formed primarily from polymer materials, and can be generally referred to as “polymeric.” In this specification, the term “polymer” includes materials such as, for examples, copolymers, and polymer materials including additives such as fillers. The core 20 can be, for example, an assembly or arrangement having data-transmission and/or power-transmission capabilities. In the illustrated embodiment, the core 20 includes a bundle of optical fibers 40 bundled within contrahelically wound binders 44, 46.

The jacket 30 includes a separation feature that facilitates access to the core 20.

In the exemplary embodiment, the separation feature is a pair of discontinuities 50 that extend along the length of the cable 30. In this specification, the term “discontinuity” indicates a portion of the jacket 30 of different material composition than the main portion of the jacket 30, the main portion being indicated by reference number 55. The main portion 55 can essentially be an annular hoop surrounding the core 20, with the discontinuities 50 extending longitudinally through the main portion 55 along the length of the cable 10. According to one aspect, the discontinuities 50 provide lines of weakness that allow the jacket to be separated 30 as shown in FIG. 1. The discontinuities 50 can conform to the profile of the main portion 55 so that the jacket 30 is a relatively uniform annulus.

FIG. 2 is a cross-section of the jacket 30 in isolation, taken on a plane perpendicular to a length of the cable 10. In the exemplary embodiment, the discontinuities 50 are bonded to the main portion of the jacket 55 when the jacket 30 is extruded. The main portion 55 and the discontinuities 50 can be formed from extrudable polymers, so that as the extrudate used to form the main portion 55 and the discontinuities 50 cools and solidifies, the extrudates become bonded at an interface 54 on each side of a discontinuity 50. When the discontinuities 50 are formed while extruding in the same step as the main portion 55 of the jacket, the bond between discontinuity 50 and the remainder of the jacket 30 can be generally described as enabled by polymer chain entanglement as the jacket 30 solidifies. The jacket 30 accordingly comprises a cohesive composite structure. In FIG. 2 the interfaces 54 are shown as clear delineations, while in practice there may be a transition region between the materials of the main portion 55 and the discontinuities 50. The curved “T” shape of the discontinuities 50 in FIG. 2 are a result of one extrusion process that can be used to form the discontinuities, but other shapes are possible.

The discontinuities 50 can be relatively narrow strips in the jacket 30, and may occupy relatively small portions of the jacket cross-sectional area AJ. For example, the discontinuities 50 can have cross-sectional areas AD that are less than 10% of A_(J), and as low as less than 5% or 3% of A_(J). In the illustrated embodiment, the discontinuities 50 each have cross-sectional areas A_(D) that are about 3% of A_(J). In FIGS. 1 and 2, two discontinuities 50 are formed in the jacket 30 to facilitate opening of the jacket as shown in FIG. 1. Depending on the form that the core 20 takes, the number, spacing, shape, composition and other aspects of the discontinuities 50 can be varied. For example, a single discontinuity in the jacket 30 may be sufficient to allow the cable jacket 30 to be opened away from the core 20. The discontinuities in FIG. 1 are shown as rectangular strips for the purposes of illustration. In practice, the discontinuities may have curved or irregular shapes, and the discontinuities will generally fracture so that they remain attached to the main portion of the jacket.

FIG. 3 is an isolated view of one of the discontinuities 50 in the jacket 30. In the illustrated embodiments, the width W of the discontinuity 50 is much greater near the exterior surface 38 of the jacket 30 than at the radially inward portion of the discontinuity 50. The discontinuities 50 can accordingly form a small, visible portion of the exterior surface of the cable jacket 30. This is due to the manufacturing process used to form the exemplary jacket, in which the extrudate used to form the discontinuity 50 was introduced from the direction 60, into the exterior of the jacket, and inwardly into the extrudate material used to form the main portion 55. The discontinuities 50 are thus progressively narrower as they extend radially inwardly. The discontinuity extends a depth D into the jacket 30, which has a thickness T. In this embodiment, the discontinuity 50 extends essentially from the exterior surface 38 to the interior surface 34 of the jacket 30. The depth D need not equal the thickness T, however. For example, discontinuities having depths D of at least 80% of the thickness T may be effective in providing tear locations for tearing the jacket 30. Discontinuities having depths D of at least 50% of the thickness T may also be effective in providing access locations for tearing the jacket 30. Depending on the jacket cross-section and materials used, discontinuities having depths D of at least 30% may be effective in facilitating access to the core.

The width W illustrated in FIG. 3 can correspond to a maximum width of the discontinuity 50. The width W is a measurement taken generally along the circumference of the jacket 30, or more specifically taken perpendicular to a radius bisecting a discontinuity 50. The width W can also be expressed as an arc length described in degrees. For example, the maximum width W of the discontinuity 50 shown in embodiment shown in FIG. 3 can be in the range of 0.5-2.0 mm. Stated alternatively, at its maximum width W, a discontinuity can traverse less than 20 degrees of arc along the circumference of the jacket 30 for small cable diameters. A discontinuity can traverse less than 10 degrees of arc for larger cables.

If an extremely thin, “film” type embodiment of discontinuity 50 is included, the maximum width W of a discontinuity can be in the range of 0.2 mm or less, and may be about 0.1 mm, corresponding to 1 degree of arc or less. Stated alternatively, at its maximum width W, a discontinuity can traverse less than 2 degrees of arc along the circumference of the jacket 30.

The materials and processes used to form the main portion 55 and the discontinuities 50 can be selected so that the interfaces 54 allow for relatively easy access to the core 20 by tearing the jacket 30 as shown in FIG. 1. The cable 10 may be constructed to meet other requirements for robustness, such as requirements for the jacket 30 stay intact under tensile loads, twisting, in temperature variations, and when subjected to other known cable test criteria, such as, for example, ICEA 460, and GR20.

The main portion 55 in the illustrated jacket 30 was extruded from medium density polyethylene (MDPE), and the discontinuities 50 were extruded from polypropylene (PP). The jacket 30 was formed in a coextrusion process so that the main portion 55 and the discontinuities 50 bonded during cooling to form relatively strong bonds at the interfaces 54. A cable formed in the process (not shown) also included water-swellable tape in the core 20 under binder threads. The cable jacket 30 was robust yet relatively low pull forces were sufficient to shear the jacket 30 along the discontinuities 50.

Without being bound by theory, Applicants believe the bond between polypropylene and polyethylene may be caused by one or both of quantities of ethylene that are compounded in the polypropylene bonding with the polyethylene (PE), and molecular entanglement between the PE and PP. According to this understanding, the amount of ethylene in the PP extrudate can be increased to increase the bond between the discontinuities and the remainder of the jacket. In general, if the main portion 55 of the jacket 30 is formed from a first polymer material, and the discontinuities are formed from a second polymer material, the discontinuities can include from 0.5%-20% by weight of the first polymer material.

If a narrow, thin film discontinuity 50 is included in the jacket, the content of the first polymer in the discontinuity can be similar to the embodiment of FIG. 2. One embodiment of a thin film discontinuity contains PP with about 9% PE. Higher PE contents, such as to up 20% PE, are also possible. PE contents of less than 0.2% in PP may result in insufficient bonding between the main portion and a discontinuity.

The inclusion of discontinuities 50 in the jacket 30 allows for a cable access procedure not available in conventional cables. Referring to FIGS. 1 and 2, the cable 10 can be accessed by scoring the end of an intact cable in the vicinity of the discontinuities 50. The cable end can be scored by, for example, a pair of snips, a knife, or some other bladed instrument. One or both sides of the torn jacket 30 can then be pulled back as shown in FIG. 1, with the jacket 30 tearing along the planes being created by the presence of the discontinuities 50. One or both sides of the jacket 30 can be pulled back to a desired length along the cable 10 to provide access to the core 20. The discontinuities are generally small enough so that they fracture and adhere to respective sides of the main portion 55 of the jacket 30. Discontinuities extending along the entire length of the cable 10 are effective in providing access to the core 20 according to this method. Shorter discontinuity lengths may also be effective however. For example, discontinuities having lengths of at least 10 centimeters along the length of the cable may be sufficient. The discontinuities 50 can be of different color than the main portion 55 so that they can be easily located and visible from the cable exterior. If the discontinuities 50 extend for a length along the jacket that is less than the entire length of the cable, different coloring of the discontinuities 50 can aid a technician in finding a location on the cable 30 to gain access.

The cable 10 can be manufactured using existing coextrusion equipment subject to minor modifications. For example, extruders from the Davis-Standard line of wire and cable extruders can be used to form a cable jacket according to the present embodiments. For example, a 1½ inch (40 mm) barrel diameter extruder and a larger barrel diameter extruder, such as a 3, 4, or 4½ inch extruder available from Davis-Standard, can be screwed into a crosshead in a configuration that would conventionally be used to extrude a cable jacket with the larger extruder, and a to extrude a stripe on the exterior of the cable jacket with the smaller extruder. In a conventional process, the stripe extrudate material is deposited on the surface of the jacket extrudate. According to the present embodiment, the flow of extrudate in the jacket extruder is diverted at the location or locations where the stripe extrudate material is introduced to the jacket extrudate. The diversion of the jacket extrudate creates a depression or trough in the flow of jacket extrudate, into which the extrudate material used to form a discontinuity is introduced. The jacket extrudate along with the with discontinuities formed therein then contracts and solidifies around a fiber optic core advancing through the crosshead.

FIG. 4 illustrates a cutaway section view of a coextrusion apparatus 100 that can be screwed into a crosshead and used to manufacture a cable according to the present embodiments. The arrows in FIG. 4 illustrate the flow direction of extrudate. FIG. 5 illustrates the coextrusion apparatus 100 including representations of the extrudate materials forming the jacket 30. The apparatus 100 can generally be constructed from commercially available components used in a cable jacketing line with the capability to extrude stripes on a cable jacket, except for the modification described below. Referring to FIGS. 4 and 5, the apparatus 100 includes a first input port 110 that receives a first molten extrudate material 112 that is used to form the main portion 55 of the jacket 30. A second input port 120 allows introduction of a second molten extrudate material 122 used to form the discontinuities 50. A cavity 130 houses a tip (not shown) that in part defines the shape of the extrusion cone 136, and the ultimate form of the cable jacket.

FIG. 6 illustrates a ring 150 that is inserted in the apparatus 100 that enables formation of the discontinuities in the flow of the first extrudate material 112. The ring 150 includes two projections 152 that act to divert the flow of the first extrudate 112. The projections 152 divert the flow of the first extrudate 112 and create a trough or depression in the extrudate flow, into which the second extrudate material 122 flows as shown in FIG. 5.

Referring to FIG. 5, to form a fiber optic cable 10, a cable core (not shown) is advanced along the centerline 102 of the apparatus 100. First extrudate material 112 is pumped into the first input port 110, which then advances through channels in the apparatus 100 and travels over the tip (not shown). The projections 152 divert the flow of extrudate 112 and create troughs. At these locations, the second extrudate material 122 is introduced into the troughs. The second extrudate material 122 therefore flows as a liquid in the flow of first extrudate material 112 as the jacket is extruded. The extrusion cone 136, which is comprised of the first and second extrudate materials 112, 122, cools and solidifies around the core to form the jacket 30.

FIG. 7 is a partial cutaway view of a fiber optic cable 310 according to a second embodiment. The cable 310 comprises a core 320 surrounded by a jacket 330, similar to the embodiment shown in FIG. 1. The jacket 330 includes a pair of discontinuities 350 that extend along the length of the cable 330. In this embodiment, the discontinuities 350 are relatively close together (e.g., within 90 degrees of each other) so that a narrow strip of jacket 330 can be peeled away from the core 320.

The cable jacket main portions 55, 355 and the discontinuities 50, 350 described in this specification can be made from various polymer materials. Either main portion or discontinuity may be made from polypropylene (PP), polyethylene (PE), or blends of materials such as a blend of PE and ethylene vinyl acetate (EVA), flame-retardant material such as flame-retardant polyethylene, flame-retardant polypropylene, polyvinyl chloride (PVC), or polyvinylidene fluoride PVDF, filled materials such as polybutylene terephthalate (PBT), a polycarbonate and/or a polyethylene (PE) material and/or an ethylene vinyl acrylate (EVA) or other blends thereof having fillers like a chalk, talc, or the like, and other materials such as a UV-curable acrylates.

In the exemplary embodiments, the first material may comprise at least 80% of a first polymer, polyethylene, by weight, and the second material comprises at least 70% of a second polymer, polypropylene, by weight and at least 0.5% of the first polymer polyethylene by weight. Higher amounts by weight of the first polymer may be included in the second material, such as at least 1.0%, or at least 2%.

In an alternative embodiment, polypropylene can be used as the first polymer primary component of the main portion of the jacket, and polyethylene can be used as the primary component in the discontinuities. In this case, amounts of polypropylene can be added to the polyethylene discontinuities to promote bonding between the discontinuities and the main portion.

In general, the desirable separation properties disclosed in this specification may be obtained by coextruding the discontinuities from a different material than the material used to form the main portion of the jacket. As an alternative method, the discontinuities may be made from the same material as the remainder of the jacket, but subjected to different curing conditions, for example.

The illustrated cores are capable of conveying fiber optic communication signals. In additional to optical fibers, or as an alternative to optical fibers, electrical conductors can be included in the cable core, so that the core is capable of conveying electrical communication signals.

Many modifications and other embodiments, within the scope of the claims will be apparent to those skilled in the art. For instance, the concepts of the present invention can be used with any suitable fiber optic cable design and/or method of manufacture. Thus, it is intended that this invention covers these modifications and embodiments as well those also apparent to those skilled in the art. 

What is claimed is:
 1. A coextrusion apparatus for manufacturing a cable jacket, the apparatus comprising: a first input port for receiving a first extrudate material; a second input port for receiving a second extrudate material; a cavity for housing an extrusion tip that in part defines a shape of an extrusion cone; and a ring for diverting an extrudate flow of the first extrudate material to create a trough in the extrudate flow into which the second extrudate material flows.
 2. The coextrusion apparatus of claim 1, wherein the ring includes two projections that act to create the trough in the extrudate flow into which the second extrudate material flows. 